# ifndef CPPAD_LOCAL_SWEEP_DYNAMIC_HPP
# define CPPAD_LOCAL_SWEEP_DYNAMIC_HPP
// SPDX-License-Identifier: EPL-2.0 OR GPL-2.0-or-later
// SPDX-FileCopyrightText: Bradley M. Bell <bradbell@seanet.com>
// SPDX-FileContributor: 2003-22 Bradley M. Bell
// ----------------------------------------------------------------------------

# include <cppad/local/play/atom_op_info.hpp>

// BEGIN_CPPAD_LOCAL_SWEEP_NAMESPACE
namespace CppAD { namespace local { namespace sweep {
/*!
\file sweep/dynamic.hpp
Under Consruction
*/

/*!
\def CPPAD_DYNAMIC_TRACE
This value is either zero or one.
Zero is the normal operational value.
If it is one, a trace for each dynamic parameter is compuation is printed.
Sometimes it is usefull to trace f.new_dynamic with the same
dynamic parameter values as during the recording
(to debug the recording process).
*/
# define CPPAD_DYNAMIC_TRACE 0

/*!
Compute dynamic parameters.

\tparam Base
The type of the parameters.

\tparam BaseVector
is a simple vector class with elements of type Base.

\param ind_dynamic
new value for the independent dynamic parameter vector.

\param all_par_vec
is the vector of all the parameters.
Ths constant parameters are inputs and the dynamic parameters are outputs.

\param dyn_par_is
is a vector with the same length as par_vec.
The i-th parameter is dynamic if and only if dyn_par_is[i] is true.

\param dyn_ind2par_ind
is a vector with length equal to the number of dynamic parameters.
The element dyn_ind2par_ind[j] is the index in all_par_vec corresponding
to the j-th dynamic parameter.
Note that if dyn_par_is[i] is false, the i-th parameter does not
appear in this vector.

\param dyn_par_op
is a vector with length equal to the number of dynamic parameters.
The element dyn_par_op_[j] is the operator for the j-th dynamic parameter.
Note that if dyn_par_is[i] is false, the i-th parameter does not
have a parameter in this list.

\param dyn_par_arg
is a vector containing the arguments for the dynamic parameters.
The first argument for the j-th dynamic parameter is dyn_par_arg[k]
where
\code
   k = NumArg( dyn_par_op[0] ) + ... + NumArg( dyn_par_op[j-1] )
\endcode
The arguments for each dynamic parameter have index value
lower than the index value for the parameter.

\param not_used_rec_base
Specifies RecBase for this call.
*/

template <class RecBase>
RecBase discrete_eval(size_t index, const RecBase& x, const RecBase& not_used)
{  return discrete<RecBase>::eval(index, x); }
template <class RecBase>
AD<RecBase> discrete_eval(
   size_t index, const AD<RecBase>& ax, const RecBase& not_used
)
{  return discrete<RecBase>::ad_eval(index, ax); }



template <class Base, class BaseVector, class RecBase>
void dynamic(
   pod_vector_maybe<Base>&       all_par_vec        ,
   const BaseVector&             ind_dynamic        ,
   const pod_vector<bool>&       dyn_par_is         ,
   const pod_vector<addr_t>&     dyn_ind2par_ind    ,
   const pod_vector<opcode_t>&   dyn_par_op         ,
   const pod_vector<addr_t>&     dyn_par_arg        ,
   const RecBase&                not_used_rec_base  )
{
   // number of dynamic parameters
   size_t num_dynamic_par = dyn_ind2par_ind.size();

   // vectors used in call to atomic fuctions
   vector<ad_type_enum> type_x;
   vector<Base>         taylor_x, taylor_y;
   vector<bool>         select_y;
# ifndef NDEBUG
   for(size_t j = 0; j < ind_dynamic.size(); ++j)
      CPPAD_ASSERT_UNKNOWN(
         dyn_par_is[j+1] && op_code_dyn( dyn_par_op[j] ) == ind_dyn
   );
# endif
# if CPPAD_DYNAMIC_TRACE
   const char* cond_exp_name[] = {
      "CondExpLt",
      "CondExpLe",
      "CondExpEq",
      "CondExpGe",
      "CondExpGt",
      "CondExpNe"
   };
   std::cout
   << std::endl
   << std::setw(10) << std::left << "index"
   << std::setw(10) << std::left << "old"
   << std::setw(10) << std::left << "new"
   << std::setw(11) << std::left << "op"
   << std::setw(26) << std::right << "dynamic i=, constant v="
   << std::endl;
# endif
   // used to hold the first two parameter arguments
   const Base* par[2];
   for(size_t j = 0; j < 2; ++j)
      par[j] = nullptr;
   //
   // Initialize index in dyn_par_arg
   size_t i_arg = 0;
   //
   // Loop throubh the dynamic parameters
   size_t i_dyn = 0;
   while(i_dyn < num_dynamic_par)
   {  // number of dynamic parameters created by this operator
      size_t n_dyn = 1;
      //
      // parameter index for this dynamic parameter
      size_t i_par = size_t( dyn_ind2par_ind[i_dyn] );
      //
# if CPPAD_DYNAMIC_TRACE
      Base old_value = all_par_vec[i_par];
# endif
      //
      // operator for this dynamic parameter
      op_code_dyn op = op_code_dyn( dyn_par_op[i_dyn] );
      //
      // number of arguments for this operator
      size_t n_arg       = num_arg_dyn(op);
      //
      // for unary or binary operators
      bool unary_or_binary = true;
      unary_or_binary &= op != atom_dyn;
      unary_or_binary &= op != cond_exp_dyn;
      unary_or_binary &= op != dis_dyn;
      unary_or_binary &= op != ind_dyn;
      unary_or_binary &= op != result_dyn;
      if( unary_or_binary )
      {  CPPAD_ASSERT_UNKNOWN( n_arg == 1 || n_arg == 2 );
           for(size_t j = 0; j < n_arg; ++j)
            par[j] = & all_par_vec[ dyn_par_arg[i_arg + j] ];
      }
      //
      switch(op)
      {
         // ---------------------------------------------------------------
         // standard_math_98
         // acos
         case acos_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = acos( *par[0] );
         break;

         // asin
         case asin_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = asin( *par[0] );
         break;

         // atan
         case atan_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = atan( *par[0] );
         break;

         // cos
         case cos_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = cos( *par[0] );
         break;

         // cosh
         case cosh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = cosh( *par[0] );
         break;

         // ind
         case ind_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 0 );
         CPPAD_ASSERT_UNKNOWN( i_par == i_dyn + 1 );
         all_par_vec[i_par] = ind_dynamic[i_dyn];
         break;

         // exp
         case exp_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = exp( *par[0] );
         break;

         // fabs
         case fabs_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = fabs( *par[0] );
         break;

         // log
         case log_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = log( *par[0] );
         break;

         // sin
         case sin_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = sin( *par[0] );
         break;

         // sinh
         case sinh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = sinh( *par[0] );
         break;

         // sqrt
         case sqrt_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = sqrt( *par[0] );
         break;

         // tan
         case tan_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = tan( *par[0] );
         break;

         // tanh
         case tanh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = tanh( *par[0] );
         break;

         // ---------------------------------------------------------------
         // asinh
         case asinh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = asinh( *par[0] );
         break;

         // acosh
         case acosh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = acosh( *par[0] );
         break;

         // atanh
         case atanh_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = atanh( *par[0] );
         break;

         // expm1
         case expm1_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = expm1( *par[0] );
         break;

         // erf
         case erf_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = erf( *par[0] );
         break;

         // erfc
         case erfc_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = erfc( *par[0] );
         break;

         // log1p
         case log1p_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = log1p( *par[0] );
         break;
         // ---------------------------------------------------------------
         // abs
         case abs_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = fabs( *par[0] );
         break;

         // add
         case add_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = *par[0] + *par[1];
         break;

         // div
         case div_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = *par[0] / *par[1];
         break;

         // mul
         case mul_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = *par[0] * *par[1];
         break;

         // neg
         case neg_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = - *par[0];
         break;

         // pow
         case pow_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = pow( *par[0], *par[1] );
         break;

         // sign
         case sign_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 1 );
         all_par_vec[i_par] = sign( *par[0] );
         break;

         // sub
         case sub_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = *par[0] - *par[1];
         break;

         // zmul
         case zmul_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 2 );
         all_par_vec[i_par] = azmul( *par[0],  *par[1] );
         break;

         // ---------------------------------------------------------------
         // discrete(index, argument)
         case dis_dyn:
         all_par_vec[i_par] = discrete_eval(
               size_t(      dyn_par_arg[i_arg + 0] ) , // index
               all_par_vec[ dyn_par_arg[i_arg + 1] ] , // argument
               RecBase(0)                              // not_used
         );
# if CPPAD_DYNAMIC_TRACE
         std::cout
         << std::setw(10) << std::left << i_par
         << std::setw(10) << std::left << old_value
         << std::setw(10) << std::left << all_par_vec[i_par]
         << "="
         << std::setw(10) << std::right << op_name_dyn(op)
         << "("
         << std::setw(12) << std::right <<
            discrete<Base>::name( size_t( dyn_par_arg[i_arg + 0] ) );
         if( dyn_par_is[ dyn_par_arg[i_arg + 1] ] )
         {  std::cout << ", i=" << std::setw(10) << std::right
            << dyn_par_arg[i_arg + 1];
         }
         else
         {  std::cout << ", v=" << std::setw(10) << std::right
            << all_par_vec[ dyn_par_arg[i_arg + 1] ];
         }
         std::cout << ")" << std::endl;
# endif
         break;

         // ---------------------------------------------------------------
         // cond_exp(cop, left, right, if_true, if_false)
         // (not yet implemented)
         case cond_exp_dyn:
         CPPAD_ASSERT_UNKNOWN( n_arg == 5 );
         all_par_vec[i_par] = CondExpOp(
            CompareOp(   dyn_par_arg[i_arg + 0] ) , // cop
            all_par_vec[ dyn_par_arg[i_arg + 1] ] , // left
            all_par_vec[ dyn_par_arg[i_arg + 2] ] , // right
            all_par_vec[ dyn_par_arg[i_arg + 3] ] , // if_true
            all_par_vec[ dyn_par_arg[i_arg + 4] ]   // if_false
         );
# if CPPAD_DYNAMIC_TRACE
         std::cout
         << std::setw(10) << std::left << i_par
         << std::setw(10) << std::left << old_value
         << std::setw(10) << std::left << all_par_vec[i_par]
         << "="
         << std::setw(10) << std::right
         << cond_exp_name[ dyn_par_arg[i_arg + 0] ]
         << "(";
         for(size_t i = 1; i < 5; ++i)
         {  if( dyn_par_is[ dyn_par_arg[i_arg + i] ] )
            {  std::cout << "i=" << std::setw(10) << std::right
               << dyn_par_arg[i_arg + i];
            }
            else
            {  std::cout << "v=" << std::setw(10) << std::right
               << all_par_vec[ dyn_par_arg[i_arg + i] ];
            }
            if( i < 4 )
               std::cout << ",";
         }
         std::cout << ")" << std::endl;
# endif
         break;
         // ---------------------------------------------------------------
         // atomic function results
         case result_dyn:
         break;

         // atomic function call
         case atom_dyn:
         {  size_t atom_index = size_t( dyn_par_arg[i_arg + 0] );
            size_t call_id    = size_t( dyn_par_arg[i_arg + 1] );
            size_t n          = size_t( dyn_par_arg[i_arg + 2] );
            size_t m          = size_t( dyn_par_arg[i_arg + 3] );
            n_dyn             = size_t( dyn_par_arg[i_arg + 4] );
            n_arg             = 6 + n + m;
            CPPAD_ASSERT_UNKNOWN(
               size_t( dyn_par_arg[i_arg + 5 + n + m] ) == n_arg
            );
            //
            size_t need_y    = size_t(dynamic_enum);
            size_t order_low = 0;
            size_t order_up  = 0;
            type_x.resize(n);
            taylor_x.resize(n);
            taylor_y.resize(m);
            select_y.resize(m);
            //
            // taylor_x, type_x
            for(size_t j = 0; j < n; ++j)
            {  addr_t arg_j = dyn_par_arg[i_arg + 5 + j];
               taylor_x[j]   = all_par_vec[ arg_j ];
               if( arg_j == 0 )
                  type_x[j] = variable_enum;
               else if ( dyn_par_is[arg_j] )
                  type_x[j] = dynamic_enum;
               else
                  type_x[j] = constant_enum;
            }
            // select_y
            for(size_t i = 0; i < m; ++i)
            {  i_par = size_t( dyn_par_arg[i_arg + 5 + n + i] );
               select_y[i] = dyn_par_is[i_par];
            }
            call_atomic_forward<Base, RecBase>(
               taylor_x,
               type_x,
               need_y,
               select_y,
               order_low,
               order_up,
               atom_index,
               call_id,
               taylor_x,
               taylor_y
            );
# if CPPAD_DYNAMIC_TRACE
            // get the name of this atomic function
            bool         set_null = false;
            size_t       type     = 0;          // set to avoid warning
            std::string name;
            void*        v_ptr    = nullptr; // set to avoid warning
            atomic_index<RecBase>(
               set_null, atom_index, type, &name, v_ptr
            );
            std::cout << "atom_dyn " << name << " arguments\n";
            for(size_t j = 0; j < n; ++j)
            {  std::cout << "index = " << j
               << ", value = " << taylor_x[j] << std::endl;
            }
            std::cout << "atom_dyn " << name << " results\n";
# endif
# ifndef NDEBUG
            size_t count_dyn = 0;
# endif
            for(size_t i = 0; i < m; ++i)
            {  i_par = size_t( dyn_par_arg[i_arg + 5 + n + i] );
               if( dyn_par_is[i_par] )
               {  CPPAD_ASSERT_UNKNOWN( i_par != 0 );
                  all_par_vec[i_par] = taylor_y[i];
# ifndef NDEBUG
                  ++count_dyn;
# endif
# if CPPAD_DYNAMIC_TRACE
                  std::cout
                  << std::setw(10) << std::left << i_par
                  << std::setw(10) << std::left << old_value
                  << std::setw(10) << std::left << all_par_vec[i_par]
                  << "= " << name << "_" << i << std::endl;
# endif
               }
            }
            CPPAD_ASSERT_UNKNOWN( count_dyn == n_dyn );
# if CPPAD_DYNAMIC_TRACE
            std::cout << "end atomic dynamic parameter results\n";
# endif
         }
         break;

         // ---------------------------------------------------------------
         default:
         std::cerr << "op_code_dyn = " << op_name_dyn(op) << std::endl;
         CPPAD_ASSERT_UNKNOWN(false);
         break;
      }
# if CPPAD_DYNAMIC_TRACE
      if(
         (op != cond_exp_dyn) &
         (op != dis_dyn )     &
         (op != atom_dyn )    &
         (op != result_dyn )  )
      {
         std::cout
         << std::setw(10) << std::left << i_par
         << std::setw(10) << std::left << old_value
         << std::setw(10) << std::left << all_par_vec[i_par]
         << "="
         << std::setw(10) << std::right << op_name_dyn(op)
         << "(";
         if( 0 < n_arg )
         {  if( dyn_par_is[ dyn_par_arg[i_arg + 0] ] )
            {  std::cout << "i=" << std::setw(10) << std::right
               << dyn_par_arg[i_arg + 0];
            }
            else
            {  std::cout << "v=" << std::setw(10) << std::right
               << all_par_vec[ dyn_par_arg[i_arg + 0] ];
            }
         }
         if( 1 < n_arg )
         {  if( dyn_par_is[ dyn_par_arg[i_arg + 1] ] )
            {  std::cout << ", i=" << std::setw(10) << std::right
               << dyn_par_arg[i_arg + 1];
            }
            else
            {  std::cout << ", v=" << std::setw(10) << std::right
               << all_par_vec[ dyn_par_arg[i_arg + 1] ];
            }
         }
         std::cout << ")" << std::endl;
      }
# endif
      i_arg += n_arg;
      i_dyn += n_dyn;
   }
   CPPAD_ASSERT_UNKNOWN( i_arg == dyn_par_arg.size() )
   return;
}

// preprocessor symbols that are local to this file
# undef CPPAD_DYNAMIC_TRACE

} } } // END_CPPAD_LOCAL_SWEEP_NAMESPACE

# endif
